Rhizochemistry and soil bacterial community are tailored to natural stress gradients.

IF 9.8 1区农林科学 Q1 SOIL SCIENCE

Soil Biology & Biochemistry Pub Date : 2024-11-26 DOI:10.1016/j.soilbio.2024.109662

Thomas Dussarrat, Claudio Latorre, Millena C. Barros Santos, Constanza Aguado-Norese, Sylvain Prigent, Francisca P. Díaz, Dominique Rolin, Mauricio González, Caroline Müller, Rodrigo A. Gutiérrez, Pierre Pétriacq

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引用次数: 0

Abstract

Plants modulate their rhizochemistry, which affects soil bacterial communities and, ultimately, plant performance. Although our understanding of rhizochemistry is growing, knowledge of its responses to abiotic constraints is limited, especially in realistic ecological contexts. Here, we combined predictive metabolomics with soil metagenomics to investigate how rhizochemistry responded to environmental constraints and how it in turn shaped soil bacterial communities across stress gradients in the Atacama Desert. We found that rhizochemical adjustments predicted the environment (i.e. elevation, R² between 96% and 74%) of two plant species, identifying rhizochemical markers for plant resilience to harsh edaphic conditions. These metabolites (e.g. glutamic and succinic acid, catechins) were consistent across years and could predict the elevation of two independent plant species, suggesting biochemical convergence. Next, convergent patterns in the dynamics of bacterial communities were also observed across the elevation gradient. Finally, rhizosphere predictors were associated with variation in composition and abundance of bacterial species. Biochemical markers and convergences as well as potential roles of associated predictive bacterial families reflected the requirements for plant life under extreme conditions. This included biological processes such as nitrogen and water starvation (e.g. glutamic and organic acids, Bradyrhizobiaceae), metal pollution (e.g. Caulobacteraceae) and plant development and defence (e.g. flavonoids, lipids, Chitinophagaceae). Overall, findings highlighted convergent patterns belowground, which represent exciting insights in the context of evolutionary biology, and may indicate unique metabolic sets also relevant for crop engineering and soil quality diagnostics. Besides, the results emphasise the need to integrate ecology with omics approaches to explore plant-soil interactions and better predict their responses to climate change.

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根瘤化学和土壤细菌群落适应自然压力梯度。

植物的根瘤化学会对土壤细菌群落产生影响，并最终影响植物的表现。虽然我们对根瘤化学的了解越来越多，但对其对非生物限制的反应的了解却很有限，尤其是在现实生态环境中。在这里，我们将预测代谢组学与土壤元基因组学相结合，研究了根瘤化学如何对环境约束做出反应，以及反过来如何在阿塔卡马沙漠的不同胁迫梯度中塑造土壤细菌群落。我们发现，根系化学调整可预测两种植物的生长环境（即海拔高度，R2 在 96% 和 74% 之间），从而确定了植物抵御恶劣气候条件的根系化学标记。这些代谢物（如谷氨酸和琥珀酸、儿茶素）在不同年份具有一致性，并能预测两个独立植物物种的海拔高度，这表明生物化学趋同。其次，在海拔梯度上也观察到细菌群落动态的趋同模式。最后，根圈预测因子与细菌物种组成和丰度的变化有关。生化标记和趋同性以及相关预测细菌家族的潜在作用反映了极端条件下植物生命的要求。这包括氮和水饥饿（如谷氨酸和有机酸，Bradyrhizobiaceae）、金属污染（如 Caulobacteraceae）以及植物发育和防御（如黄酮类、脂类，Chitinophagaceae）等生物过程。总之，研究结果突显了地下的趋同模式，这代表了进化生物学方面令人兴奋的见解，并可能表明独特的代谢集也与作物工程和土壤质量诊断有关。此外，研究结果还强调有必要将生态学与全息方法相结合，以探索植物与土壤之间的相互作用，并更好地预测它们对气候变化的反应。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Soil Biology & Biochemistry 农林科学-土壤科学

CiteScore

16.90

自引率

9.30%

发文量

312

审稿时长

49 days

期刊介绍： Soil Biology & Biochemistry publishes original research articles of international significance focusing on biological processes in soil and their applications to soil and environmental quality. Major topics include the ecology and biochemical processes of soil organisms, their effects on the environment, and interactions with plants. The journal also welcomes state-of-the-art reviews and discussions on contemporary research in soil biology and biochemistry.